Method and apparatus for remote indication



1937- G. a. LINDERMAN. JR 2,089,701

METHOD AND APPARATUS FOR REMOTE INDICATION File Aug. 14. 1953 e Shets-Sheet 1 GARRETT B. LINDERMAN JR.

MM/qjrm Gum M 5 Aug. 10, 1937'. U DERMA'N, JR 2,089,701

METHOD AND APPARATUS FOR REMOTE INDICATION Filed Aug. 14, 1933 6 Sheets-Sheet 2 l INSULATION 42 I I v I" 64 I IN 63 I jgsuunou A46 79 Ml INSULATION 3 mun M msuur/ou A52 2 GARRETT B. LINDERMAN JR.

1937. G. B. LINDERMAN. JR 0 ,1

METHOD AND APPARATUS FOR REMOTE INDICATION Filed Au'g. I4, 1933 6 Sheets-Sheet 3 GARRETT B. LINDERMAN JR.

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.6. B.- LINDERMAN, JR

METHOD AND APPARATUS FOR REMOTE INDICATION 6 Sheets-Sheet 4 Aug. .10, 1937.

Filed Aug. 14, 1953 I' III E 334 T 7/ 326 3 40 5 56 5-, GARRETT UNDERMAN \JR Aug. 10, 1937. G. B. LINDERMANE JR 8 METHOD AND APPARATUS FOR REMOTE INDICATION Filed Aug. 14, 1933 6 Sheets-Sheet 5 INSULATION GARRETT B. LlNDERMAN JR.

1937. G. B. LINDERMAN. JR ,701.

METHOD AND APPARATUS FOR REMOTE INDICATION Filed Aug. 14, 1933 6 Sheets-Sheet 6 c5000 00 0 0 O O O 60 I] 6/ M I IM' O 60 62 O 26/ 2 w 260 265 3 8 264 m Q g 0 t 1 z 1': L l

O a O 250 8 O O O o O I O 0 W ll O 0 MW 0 0 i O O O 0 INSULATION FIG. 13

swam/bot 67 289 9 GARRETT B LINDERMAN JR.

288 A/Z/zzM W T mini-M 5 Patented Aug. 10, 1937 UNITED STATES PATENT OFFICE METHOD AND APPARATUS FOR REMOTE INDICATION Application August 14, 1933, Serial No. 685,137

3 Claims.

This invention relates .to apparatus for accurately-indicating orrecording a variable quantity, motion or factor.

More particularly the invention relates to apparatus for indicating or recording at a distance the movement of an exploring device, such as a float, in major linear units and fractional units or fractions of the major unit with such a degree of precision as to be acceptable as a basis for 19 computing charges or other commercial data.

The present invention is especially applicable to the measurement of the level of liquid in a storage reservoir or a vessel such as a tank, as for 4 example, in the petroleum industry, where tanks many feet in diameter are used for storing crude oil or refinery products. It is essential that the level of liquid in the tank be determined accurately to account for loss by waste, evaporation or through other sources of loss, and where the 20 cost or value of the liquid added to or withdrawn from the tank is computed from the diiference in level of the liquid, it is important to accurately measure the level of the liquid. The practice in oil industry has been to send men out provided 5 with gas masks to manually gauge tanks holding petroleumor refinery products, and because of the hazardous nature of this operation, two men are employed at ,the work to minimize the danger of a fatal accident in the event that 0 one of the men is asphyxiated in the course of making the measurements.

Proposed telemetric systems of the prior art rely upon a single transmission device precluding the possibility of obtaining the necessary de- 35 gree of accuracy for measuring valuable fluids with any form of receiver. Where unit and fractional unit transmission means have been employed, transmission of varying electrical currents has been relied upon to operate indicating 40 instruments. Such prior art systems do not give results which are sufficiently accurate for the purpose outlined above as an example of an important field of use to which my invention is especially applicable. I have discovered that ex- 45'tremely accurate resultsnot heretofore obtainable 'may be realized by combining in a novel manner, unit and fractional unit transmission means in a system using a zero deflection or null method of measurement.

50 For measuring the level of a liquid in a tank at a place remote therefrom, the present invention embodies a variable electrical function, as for example, a resistance, governed by the height of liquid in the tank, which forms part of a balanc- 55 ing circuit, containing a similar electrical function, and having means for measuring the functrical function varied by the first function at a.

different rate is employed, and by introducing this second function into a balancing circuit, which may be the same balancing circuit above mentioned, and providing means calibrated in small units, the large units and fractional large units can be accurately measured when a condition of balance is reached or recorded when the condition of balance is maintained;

Accordingly, one object of the present invention resides in the provision of apparatus for indicating or recording the level of liquid in a tank or other container in large and small units or large units and fractions thereof with extreme accuracy.

A further object of the present invention is to provide an apparatus forindicating or recording the level of liquid in a tank or other receptacle in large and small units, or large units and fractions thereof with extreme accuracy at a point remote therefrom over a single existing com- -mercial communication channel with a single indicator or recording receiver. 7

A further object therefore resides in the provision of a system including a pair of variable elec--.

trical functions and a null system for determining said functions under conditions of balance in the system.

A further object of this invention is the provision of separate means for indicating or re-- cording an unknown quantity at a distance, said means being controlled by the same factor but whose responses are unlike yet proportionally related, one means operating to indicate large units and another means which may comprise a part of the first mentioned means operating to indicate fractions of the large units whereby readings may be obtained to a high degree of accuracy.

3 A further object of this invention is the provision of separate means for remotely indicating an unknown quantity, the means being controlled by the same factor but responding differently thereto in a definite proportioned relation whereby the unknown quantity is accurately indicated in definite linear units and fractions thereof.

. Still a further object of this invention is the provision of a multiple transmission apparatus to obtain accurate readings in different linear units proportional to the movement of different I elements of the apparatus.

A further object of this invention is the priivision in a remote indicator system of separate means controlled by the same factor but whose responses are unlike, in combination with a null system for determining the value of the responses to obtain a desired reading.

5 A further object of this invention is the provision in a remote indicator system of separate transmission means controlled by the same factor but responding differently thereto in a predetermined proportional relation, means being provided for selective connection with said separate transmission means to determine the value of each response, by balancing conditions in the difierent means.

A further object of this invention is the provision in a remote indicator system of separate transmission means controlled by the same factor but responding differently thereto in a predetermined proportional relation and measuring means for selective connection with the separate transmission means having a plurality of indicators, the indicator corresponding to the connected transmitting means only being readable for the purpose of avoiding mistakes in measuring the response of the transmission means.

A still further object of this invention is the provision of a system and apparatus for accurately measuring at a remote point a varying quantity in large and small or fractional units with a single receiver and a two element transmitter connection of either element of the transmitter to the receiver being controlled remotely over the circuit which is used for transmission of measurements of the varying-quantity.

A still further object of the present invention is to provide a novel measuring means including a plurality of graduated scales, one only of which is visible at a time,

Still a further object is to provide a multiple transmitter containing two or more elements for indicating an unknown v'alue, theelements of v the transmitter being geared to move in a predetermined relation whereby when controlled by the same factor they will give unlike yet proportionally predetermined responses, means being provided whereby each transmitter may be con-- nected thereto individually and the value of its response accurately determined.

Afurther object of this. invention is the provision of means in connection with individual transmission elements whereby the response of either of said elements may be utilized to determine an unknown value.

A further object is the provision of means in connection with individual transmission elements whereby at least one element is maintained in responsive relation when another .element is incapable of response. Still a further object is the provision of means in connection with synchronized transmission elements which are arranged so as to be incapable of response at certain stages whereby one element is brought into responsive relation as another element approaches its non-responsive stage, thereby maintaining at least one of said elements in responsive relation.

These and otherobjects will be apparent from a consideration of the following description taken in connection with the accompanying drawings, wherein: Figure 1 is a schematic diagram of an electrical circuit preferably employed in connection with the embodiment illustrated in Figure 2;

Figure 1b is a schematic diagram of the unit transmitter of Figures 2 to 6; Figure 2 is an elevation of a preferred embodiment of the invention with the enclosing casing taken in section;

Figure 6 is a detailed view in plan of the switch mounted above the upper insulating disc in Figure 2;

Figure 7 is a view, partly in section, of a receiver for use'in connection with the modiflcation shown in Figures 1 to 6;

Figure 8 is a view in elevation, taken partly in section, of another preferred embodiment of the invention;

Figure 9 is a plan view of the embodiment of Figure 8;

Figure 10 is a schematic diagram of an electrical circuit preferably employed in connection with the embodiment of Figure 8;

Figures 11, 12, 13' and 14 are schematic diagrams of preferred electrical circuits that may be employed as modifications; and

Figure 15 is a schematic diagram of a modification employing a' potentiometer circuit and suitable for use on telephone lines for long distance transmission.

The invention will be hereinafter described as being particul arly applicable to the accurate measurement of the depth of liquid in a tank but while I have chosen to illustrate and describe my invention in' connection with this particular use, it is to be understood that the invention may be effectively practiced in connection with the measurement of any varying quantity and can be used to advantage for continuously recording variations in the quantity to be studied or measured.

Referring to the drawings in detail, andfcr the present particularly to Figure 1, the specific embodiment of the apparatus diagrammatically illustrated comprises a transmitter T, and a receiver R. The transmitter comprises a slide wire l2' across the ends of which is shunted a resistance III to accurately determine the total resistance of the wire between the ends I! and I 5. Preferably the wire i2 is in practice mounted upon a rotatable disc so as to slidably engage a fixed contact member I3, and the ends of the wire i2 are connected to metal contact rings 16 and 'i l which rotate therewith. The contacts or brushes l8 and I9 make a slidingconn'ection with the rings l6 and I1 respectively.

A second wire 22 is mounted on a suitable disc and is adapted to be rotated in a predetermined relation to the wire l2. For example, for each revolution of the wire l2 the wire 22 may make of a revolution. The wire 22 likewise has a resistance Hi shunted across its ends 24 and 25 to accurately determine the total resistance of the wire between the ends, and 25. A similar contact member 23 makes sliding contact with the wire 22 intermediate its ends 24 and 25, which are connected to the metal rings 26 and 21 adapted to rotate therewith. Contacts or brushes 28 and 29 make similar sliding connection with the rings 22 and 21 respectively. a

From the description so far pursued it will be apparent that the slide wire I2 is adapted to be moved or rotated in any suitable manner, as for example, by a float; and by suitable gearing, the wire 22 is rotated or movedat a slower rate. The

contacts I3 and 23 will move along the wires I2 and 22 respectively to vary the effective resistance thereof, the effective resistance of wire 22 being varied only /5 that of wire I2. For example, the total resistance of wire 22 may represent the maximum range of the instrument, and if the level of a liquid is being measured this will correspond, for example, to 50 feet. The full resistance of wire I2 in such case will represent one foot. It will be seen that a difference in level of the liquid of one foot will cause the wire I2 to make a complete rotation whereas the wire 22 would make only of a revolution, while, for example, a difference in level of five feet would cause the wire I2. to make'5 revolutions while wire 22 turns only one tenth of a revolution. The zero positions of the scales for wires I2 and 22 coincide on the receiver so that when the contact 23 is at exactly a foot division on wire 22 the contact I3 is at end I5 of wire I2.

25 The arrangement so far described comprises a two unit transmitter which may be used in conjunction with the receiver R a description of which follows. According to my invention I provide means for accurately measuring the position 0f contact I3 on the wire l2 in conjunction with means which eliminates the effect of the gap which necessarily exists between the ends I4 and I5 of wire- I2, and these means will be described hereinafter in detail.

5 The preferred type of receiver now will be described. This consists of a modified Wheatstone bridge circuit comprising variable resistances 3| and 32 suitably shunted by the resistances 33 and 34 so that-the total resistance across wire 32 is twice that across wire 3|. A suitable 40 resistance 35 isinterposed between the'ends of resistances 3| and 32. One terminal of the galvanometer 36 is connected by a wire 31 to a sliding contact 38 that moves along the wire 32, the other terminal being connected by a wire 39 45 in fixed relation at 39 between the ends of fixed equal resistances 40 and 4|. A resistance .42 equal to resistance 35 is located adjacent wire 32. The battery 43 is connected through a lead 44, switch 45 and lead 46 to a movable. contact member 41 which slidably engages the wire 3|. The contacts 38 and 41 are adapted to be moved over their respective wires 32 and 3| in unison, and as one of these wires, namely 32, is twice the resistanceof the other, it will be seen that the effective resistance of wire 32 changes twice as fast as that of .wire 3|.

The resistances 4| and 42 are connected by a double throw switch S manually operated to the ends of wires |2or 22 as desired. For this purpose resistance 4| is connected by a lead wire 48 to a movable member 59 of a double switch which connects across the contacts 5| or 52, while a lead wire 49 connects. resistance42 to the member 53 of said double throw switch which connects across the contacts 54 or 55. Through the lead wires 56 and 58 the ends of wire I2 are connected to the a switch contacts 52 and 54, while through the lead wires 51 and 59 the ends of wire 22 are similarly connected to the switch contacts 5| and 55. This switching arrangement permits the use of one receiver for indicating or measuring the effective resistance of each of wires Hand 22.

The other terminal wire 60 of battery 43 is permanently connected to the lead wire 6| which in turn is connected to the sliding contact 23 of wire 22. Another lead wire 62 permanentlyconnected to the lead wire 50 at one end is connected at its other end through the wire 61 to the movable switch m'ember 63 which, as shown, contacts with the fixed switch terminal64. A lead wire 65 connects this terminal to the sliding contact I3 on wire I2.

It will be apparent that in the modified Wheatstone bride circuit all the moving contacts are in the galvanometer or battery circuit where they cannot affect the accuracy of the measurement. In practice, the two slide wires 3| and 32 are mounted on a. single disc and move in unison and the resistances 35 and 40 are so proportioned that at all. points on the slide wires the resistance from 39 to 41 equals the resistance from 38, to 41 thus keeping the ratio arms of the bridge equal. As the disc .is rotated the resistance through 42 to 38 varies, and as resistance 39 to 41- equals resistance 38 to 41, the bridge is balanced when resistance 38 to 53 equals resistance 30 to 50. With the leads 51 and 59 equal the variable resistance of slide wire 32 through 4 9 equals the effective resistance of slide wire 22. The total resistance of leads 49 and 59 equals the total resistance of 48 and 51 so that they do not affect the reading of the instrument; (Likewise leads 56 and 58 are equal.) The slide wire 32 therefore can be calibrated, or preferably, a calibrated scale can be attached thereto. In the present device two scales are employed one of which represents a foot and is subgraduated in inches and fractions of an inch, and the other of which represent a number of feet, for example 50 feet, and is graduated in feet and large fractions of a foot. The galvanometer 36 is employed to indicate a condition of balance that is, when the scale on wire 32 equals the effective resistance of wire 22. v

The operation of the portion of Figure 1 so far described will be explained in connection with its use in a tank gauge, although it is to be understood the invention is not limited thereto. A variation in level of the liquid in the tank will move the contact 23 to a certain point along the wire 22, and the movable contact I3 likewise will be moved along the wire I2. However, because of the gearing between the wires 22 and I3. for each equ valent foot, i. e., of its length, that wire 22 moves the wire I2 will move its entire length. If, for example, the contact 23 moves to a point on wire 22 that represents 10 feet 6: inches, the contact I3 will move to a point correspondingto the exact fractional foot, for example, 6.2 in. In order to read the gauge the switch members 59, 53' are thrown in contact with the terminals 5|, 55, respectively, thereby bringing the wire 22 into the circuit. The effective resistance of wire 22 then becomes the distance 23 to 24, and by turning the disc carry-, ing the slide wires 3| and 32 till the galvanometer shows zero deflection, the height of the liquid in feet will be shown on the foot scale. This, it has been assumed, is 10.5: ft. The switch members 59, 53 now arefthrown in contact with the terminals 52, 54 respectively, thereby bringing the wire l2 into the circuit and cutting out the wire 22. The effective resistance of wire I2 now is the distance from I3 to- I4, and by again turning the disc carrying the slide wires 3| and 32 till the galvanometer ShCV-JS zero deflection the last fraction of the previous reading can be a'c- 'curately read on the fractional foot" scale. This reading will be 6.2 in. in accordance with the previous assumption so that the total .reading apparently a quantity causes a condition to arise where the precise reading is in doubt. With the two section trans mitter illustrated, when the contact II lies at an end of the slide wire I2 the correct level is which can be expressed in the large units without a fractional part. For example, with a transmitter using slide wires I2 and 22 as previously described, if the contact 22 bears on slide wire 22 at a point which represents 10 feet, and the contact II lies in the break between the ends I4 and i5 01" wire I2, the reading will' apparently be 10 feet. If, however, readings could be taken for the full 360 degrees of rotation of the disc carrying wire I2, a small fraction of an inch may be indicated as the 5 amount which is to be addedto or subtracted from the reading of 10 feet. Also, with a transmitter embodying slide wires l2 and 22, ii a fault existed in the circuits connecting slide wire I2 30 to the receiver this would not be readily detected if readings in large units very close to even figures were obtained with switch 8 in contact with wire points II and 55.

Other disadvantages would arise if a recording receiver were employed using an automatic balancing scheme. If the transmitting slide wire I2 stopped with contact I I in the open circuit position between the ends II and I5, the recording pen would produce an irregular record if the recorder galvanometer were under damped. Also it, due to the condition of the function being transmitted, the slide wire I 2 should oscillate with the contact I3 near the break 'so that the contact I! would come in contact alternately with ends II and I5, the recorder pen would move from one end of the scale to the other, producing a poor record.

The foregoing disadvantages are overcome by the arrangement now to be described: 7

The slide wire I2 has interposed between the end I5 and ring II a resistance" which is equal to one third the resistance between the ends II and IS. The disc which carries slide wire I2 also carries a slide wire 12 which is equal to slide wire and is connected to the ring II at one end I3.

55 A resistance similar to resistance bridges the slide wire I2. A-resistance I5 is interposed between the other end II and the ring I 8, this resistancebeing equal to resistance 10. As the gearing ratio between slide wire I2 and wire 22 is l th, and as it is desired to have the fractional unit transmitter indicate hundredths of a foot, the resistance I6 is connected to slide wire 22 to keep the total resistance of wires 22 and 18 equal to one half of wires I2 and III.

Figure lb shows diagrammatically the relative positions occupied by slide wires I2 and I2 when mounted in position in a transmitter. The structure of the mounting for the slide wires will be fully described later in connection with the de- 0 scription of a preferred form of transmitt r iilustratedby Figures 2 to-6 of the drawings employing the arrangement of Figures 1 and 1b.

Referring to Figures '1 and lb, the end I of slide.

wire I2 beginsat a point corresponding to zero position of slide wire 22 and for each revolution of a given point on Figure 1b the slide wire 22 will rotate t g th of its length. A contact member 11 engages slide wire I2, and as shown by Figure lb which illustrates the preferred relative positions of wires I2 and I2, the contact TI is directly in line with contact I3 which engages wire I2. Slide wire I2 is dispe ced from slide wire I2 and begins at 30% of the circumference of the transmitter, that is, one-third the length of wire I2, and ends at about 120% of the circumference, and resistance I5 extends the range of this slide wire back one-third to the zero 3 nt. The range of slide wire I2 is extended to about 120% of the circumference by resistance I0 which as previously stated is one-third of the value of the resistance of wire I2 between the ends I4 and I 5.

With the arrangement just described, it will be seen that there is an overlap in the range of these wires from zero to of the circumference and contact 11 enables readings to be taken from about 90% of the circumference to over 100% of the circumference continuously and without interruption, while contact I3 permits readings to be taken from about zero to about 90% of the circumference so that the two contacts in combination will cover the entire unit range of the instrument and a small overlap without showing a dead space caused by the gaps between the ends of the wires. As will hereinafter appear, the fractional unit indicator or recorder will be calibrated from zero to twelve inches in black numerals corresponding to 100% revolution of wires I2 and I2, and a duplicate scale in red numerals from zero to two'inches with the red zero coinciding with the black I2 will extend the receiver readings to correspond to the 20% overlap.

The contacts I3 and II are continually in contact with their respective wires, and a switch member is employed to shift the connection from one or the other in the circuit; This switch member is operated automatically and consists of a movable member 83 adapted to contact the switch contact 64 and a second movable member 66 connected by wire 61 thereto, and adapted to contact the switch contact Iii, the latter being connected to contact 11 by a lead wire I9.-

The principle of operation of the switch arrangement will now be described with reference to Figures 1 and lb: For the sake of clearness of description, it will be assumed that slide wires I2 and I2 are stationary and that contacts I3,

and I1 follow the wires by progressing in a clockwise direction around Figure 1b for an increase in the function to be measured, the arrow indicating the direction of movement of the slide wires. Starting with the zero position of the slide wire 22 or at an even foot position, contact I3 moves clockwise with an increase in the function to be measured to the position shown by dotted ,arrowi3. At an intermediate point indicated by the dotted arrow 11 as will be explained, contact II is connected into the circuit by switch 82. At the point indicated by dotted arrow II, the switch '3 contacting point 64 (Figure l) is opened and switch 66 is closed to introduce wire I2 and contact 11 into the circuit. This operation of the switch preferably occurs at about 85% of a revolution of the contacts as is indicated by the designation 85%" on Figure 1b. At this point ,the effective resistance of the wire I2 is from I4 to dotted line contact I3. In switching over to wire 12 thefbalance of the circuit is not upset because the effective resistance of wire I2 is from "to the point designated 85%" to which is added the resistance 15 which makes the resistance of the slide wires l2 and 12 equal from point ll to dotted arrow l3.

Continued movement of the contacts 13 and 11 in a clockwise direction which is equivalent for the purpose of this description, to actual movement of slide wires l2 and 12 in a counterclockwise direction, brings these contacts to the position indicated by the dotted arrow 11 at a point corresponding to about of a revolution, measuring from the zero position it, at which point switch 66 is opened and switch member 63 is closed thereby switching wire 12 into the circuit again. At this point the effec- 15 tive resistance of wire 12 is from zero point H, because of the efiect of resistance 15, to dotted line contact 11 which corresponds to 115% of a full scale reading of the fractional transmitter. The eifective resistance of the slide wire l2 at this point is only from zero point H to the full line arrow 13 which corresponds to only 15% of a full scale reading of slide wire i2. In switching over to wire 12 at this point the balance is upset. However, this is provided for by the scale of the receiver shown in Figure 7 as will hereinafter appear. Continued rotation in the same direction causes a repetition of the switch action just described.

when the direction of rotation is reversed by 0 reason of a decrease in the function being measured, the slide wires 12 and 12 turn in a clockwise direction as viewed on Figure 1b. This is equivalent to a counterclockwise movement of contacts 13 and 11 and it will be assumed that these contacts follow the wires by progressing in a counterclockwise direction around Figure 1b for a decrease in the function to be measured. Again, as before, starting with a position of the slide wire 22 so that contact I3 is in contact with 0 wire 12, upon a decrease in the function to be measured, contact 13 moves counterclockwise to the position indicated by dotted arrow i3.

At this time switch 83 operates to disconnect contact i3 and switch 66 is closed to introduce wire 12 and contact 11 into the circuit. This operation 'of the switch preferably occurs at about 5% of a revolution measuring clockwise around Figure 11) beginning at'point l4 and it will be seen that the switch operation occurs 5 near the point designated by dotted arrow 13.

In switching over to wire 12 the balance is upset for the reason previously considered in connection with the description of the switch action which occurs at dotted arrow 11 when the func- 5 tion to be measured is increasing in value.

Continued movement of the contacts 13 and. -11 in the reverse direction with a decreasing value of the function being measured brings these contacts to a position indicated by dotted arrow 11', at a point corresponding to about 75% of a revolution as measured from point it in a clockwise direction around Figure 1b. At this point, switch 86 is opened and switch 63 is closed bringing contact 13 into the circuit. The

balance of the circuit is not upset in switching over to the wire 12 at this point for the reason previously set forth in connection with the switch operation which occurs 'at the point in-' dicated by dotted arrow 13. Continued rotation of the slide wires in a clockwise direction causes a repetition of the action just described.

It will be seen from the foregoing that on an increase in the function to be measured, the

change from the slide wire 12 to the slide wire I2 is made at the point indicated by the dotted arrow 11 which is at of a revolution, and that on a decrease in the function if slide wire I2 is originally in the circuit a shiftpccurs to the slide wire 12 at 5% of a revolution, and the change back to wire l2 occurs at 75% of a revolution. This range of approximately 10% of a revolution between shifting points is preferably provided so that if the liquid level varies when the contacts are near the shift points the oscillation near the transfer point will not cause repeated operation oi the switches 63 and 68 with consequent jumping from one end of the scale to the other between the 5% and 115% points. The same range is provided between dotted arrow l3 to full line arrow 13' from 75% to 85%.

The receiver as shown in Figure 7 comprises a case 85 having a cover 86 for supporting the working parts, the cover being shown broken away. The wire 32 and wire 3i, the latter not being shown in Figure 7, are mounted side by side on the periphery of cylinder 81 so as to rotate in unison therewith. Cylinder or disc 81 is arranged to be turned slightly less than a full revolution. The spring contact member 38 mounted on a support 88 makes a sliding contact with wire 32. Contact member 41, not shown in Figure '1', is likewise secured to support 88 and contacts wire 31. The disc 81 may be rotated by means of knob 89, and as hereinbefore explained, as wire 32 is twice the resistance of wire 3!, and as the wires 31 and 32 rotate in unison with the disc 81, the ratio arms of the bridgecircuit are maintained equal. The disc 81 has near its periphery a scale F which rotates therewith and is graduated from zero to 50 feet corresponding to the full length of wire 22. A concentric scale G likewise secured on the disc 81 and rotatable therewith is graduated in inches from zero to twelve inches in black numerals then to two inches in red numerals with the black i2 and red zero at the same point,

this full scale corresponding to about of a revolution of wires 12 and 12, that is, to the combined overlapped lengths of said wires. The red scale therefore is a duplicate of a portion of the black scale. The cover 88 of the case has a suitable window 81 therein with a hair line.

32 and. scales F and G until the galvanometer36 shows zero deflection. When wire 22 is connected to the receiver by switch S the scale F is to be read. To take the reading of wire i2..or 12 the switch S must be shifted to connect these wires to the receiver, and as the effective resistance of wire 12 or 12 is ordinarily not the same as the effective resistance of wire 22, this shifting of switch S upsets the balance of the receiving circuit so that the disc 81 again must be turned till the galvanometer shows zero deflection to take the reading on scale G. When the readings of scales F and G are hereinafter referred to the above procedure involving the proper connection of switch S and rotation of disc 81 for balancing of the galvanometer will be understood.

Referring again to Figures 1, 1b and 7, it will be seen that when slide wire 22 is at zero position at 24, the end It oi wire 12 is likewise'at zero position but is not connected in the circuit, but

wire 12 with contact I1 opposite the zero position is in the circuit. In'this position the scale F would indicate zero feet, and scale G would likewise indicate red zero inches at the red zero. If wire 22 now moves an amount equivalent to .15 foot the scale F will register plus zero feet and scale G will register 1.8 inches on the red scale so that the reading is exactly 1.8 inches. That is, the inch reading is always added to the last full foot reading of scale F. However, at this point the contact 11 will be at the position 11 shown in-Figure 1b and with the toggle switch Just ready to jump. Upon further turning of the slide wires the switch disconnects wire contact 11 and connects contact I3 thus unbalancing the circuit, and

to restore the galvanometer to a position of balance to take a reading the disc 01 must be reversely rotated to the corresponding position on the black scale, that is, 1.8 inches plus at which point the reading is taken. Upon further turning of the slide wires the readings on both scales F and G will mount until the next full foot is passed and this action will be repeated. Hence it will be seen that upon balancing the receiver circuit if the reading on scale F is apparently a full foot division, the exact measurement can be obtained by connecting wires I2 and I2 into the receiver circuit through switch S and reading the measurement thereof on scale G. Whether the scale G reads in the red numerals above twelve or in the black scale the reading always is the nearest full foot indicated on scale F plus the reading on the scale G above the red or black zero as the case may be.

Once the switch action has taken place so that the scale G reads 1.8 inches plus in the black, if the direction of rotation of wires 22, I2 and 12 reverses due to a decrease in the liquid level the switch will not reverse at the 1.8 inch black reading. A ten per cent difference between switching points is provided, as previously explained in connection with the diagram of Figure 1b, and this permits readings to be taken until a position of balance of about .6 in. .is reached (i. e. 5% of 12 in.) at which point the switch action reverses throwing wire I2 into the circuit.

This unbalances the receiving circuit so that the scale G must now be shifted to the red to take a proper reading. It will be observed that as no unbalancing action occurs on the decline at 75% where the switch shifts from TI to I2 or on the increase at 85% where the switch action shifts from I3 to I1, it is possible to take continuous readings over a range from .6 to 13.8 inches on scale G.

Referring to Figure 2, which shows a preferred construction of the transmitter schematically illustrated in Figures 1 and 1b, the U-shaped frame I00 is adapted to be inserted into a box so or enclosure having a top I02 in which the frame is secured, and the whole apparatus is adapted to be placed at or near the top of a tank above the level of liquid therein. A central shaft I03 extends through the frame and is Journalled at 06 one end in the bottom part of the frame and at the other end ina cross member I04 near the top of the frame, and has a bevel gear I00 suitably secured thereto at its upper end. The top of the frame has a thickened portion through which passes the shaft I00 having the bevel gear III suitably secured on its inner end and meshing with the bevel gear I05 whereby the shaft I 03 may be rotated in unison therewith. Shaft I00 is adapted to be rotated by movement of a float on an endless belt (not shown) or other suitable element operated by the level of liquid in a tank (not shown). Preferably the shaft I06 is journalled in ball bearings I08 or other suitable antifrictlon bearings. It will be evident that if so desired the shaft I05 and gears I05 and I01 can be eliminated and shaft I03 can be extended so that it will be driven directly from the float member thereby eliminating possible play in the gearing arrangement shown.

Suitably secured on the shaft I03 to rotate therewith are the insulation discs H0 and III about the peripheries of which are wound the sliding resistance wires 12 and I 2,- respectively. Wire I2 is clamped in place at its end I4, I5 by the insulation plate I09 which is held on disc II I in any suitable manner, and one end of the wire I2 passes through the disc III and con tacts with a collector ring I6 secured to a face of the disc III .in any suitable manner. The other end of the wire passes through the discs I I I and I I0 and to a suitable auxiliary resistance 10 (Figures 1 and 1b) in the disc and to a collector ring I! on the opposite side of the bottom disc H0. On the disc IIO the similarly wound sliding contact wire 'I2has its end 14, I3 secured in a similar manner by the insulation plate III disposed at an angle of about 108 from the plate I09. The one end 14 of the wire 12 passes through the discs II 0 and III, and to a suitable auxiliary resistance 15 in the disc and to a collector ring I6, and the other end I3 of the wire I2 is secured to the collector ring ii. The resistances l0 and I5 are embedded in the discs H0 and III- A spring pressed brush member I0 is clamped at one end to a shelf I21 on the-frame I00 and is insulated therefrom in any suitable manner,

the other end of the brush member resiliently bearing on the collector ring l6 and making sliding electrical contact therewith at all times. A similar spring pressed brush member I 9 on the shelf I29 (Figure 3) secured thereto and insulated therefrom in the same way makes sliding contact with the collector ring I1. Lead wires 55 and 50 are connected to the brush members I3 and I9 respectively at one end and to suitable binding posts at their other ends in the top I02.

The spring pressed sliding contacts I3 and '11 are secured to the frame I00 and insulated therefrom in any suitable manner, and make resilient sliding contact with the wires I2 and I2 respectively. A guard I34 issecured to one face of the disc III and projects over its edge adjacent plate I09, so that when the disc III is rotated to the position with the plate I09 opposite the contact I3 the guard I34 bears against the contact I3 and moves it out of engagement with the wire I2 while the contact" continues tov bear on the wire I2 as shown in Figure 2. Now, as -rotation of the discs is continued the guard I34 moves out of contact with the contact I3 permitting it to reengage the wire I2, the

contact 11 inthe meantimecontinuously engaging the wire 12 until the lower guard I 35 under the plate II! on disc H0 is brought around into contact with the contact TI and moves it out of engagement with the wire 12, the contact I3 meanwhile continuously. engaging the wire I2. Further rotary movement of the discs III and H0 brings the guard I35 out of engagement with the contact 11 which then again contacts wire 12. It will be seen, therefore, that v contacts I3 and TI continuously engage their respective wires and I2, except at the plates I09 and H1, and in order that current shall flow through only one contact at a time a special toggle switch is provided. i

The toggle switch construction included in the present invention comprises'a pivot rod or shaft I36 (Figures 2 and 6) rotatably secured in an extension I31 at the top of the main frame I and suitably insulated therefrom. On this shaft is secured an eccentric or cam shaped collar [0 I38 adapted to rotate therewith. The switch operating bar I39 is suitably secured to the pivot shaft I36 as by a collar and has both ends free, the ends being bifurcated as shown to form the tines I4I, I42 and MI 15 and I42. A pin l43 projecting from the face of the disc III is adapted to contact with either of the tines I4I or I42 depending on the direction of rotation to shift the bar I39 about the pivot shaft I36 turning the pivot therewith to the 20 position as shown in dotted lines in Figure 6 when rotation is in the direction of thearrow.

As shown in Figure 6 the lead wire 65 is connected at one end with the contact I3 and at its other end is electrically connected with fixed 25 spring switch member 64 secured to the frame I00 between insulation blocks I41 and I48. A movable switch member 63 is composed of two spring portions I54 and I55 secured together at I51, and the spring portion I55 carries at its 30 end a bearing block I53 of insulation material -which is adapted to ride on cam collar I38. In the position of the switch shown in Figure 6 the cam collar I38 holds the bearing block I53 lowered thus keeping switch member 63 out of 35 contact with fixed spring switch member 64. In this position sliding contact I3 has been contacting wire I2 but the circuit through members 63 and 65 is not closed. Diametrically opposite to bearing block I53 is the similar bearing block 40 I52 which is carried at the end of a spring portion I49 likewise secured to a spring member I50 at II to form a switch member 66, and between which extends the fixed spring switch member 18, all of which are similarly secured 45 in insulation blocks. A lead wire 19 contacts at one end with the contact 11 and. at its other end with fixed switch member 18. The movable switch member 63 and 66 are interconnected by a wire 61 so that in effect they form one mov- 50 able switch. It will be apparent because of the shape of cam collar I38, when contact between switch elements 64 and 63 is broken, the contact between switch elements 66 and 18 is established as in the position of the switches shown 5 in Figure 6 so that the current from only contact 11 and resistance 12 is conducted through switch elements 66 and 18 by wire 62' to the binding post in ,thetop cover.

\ Upon,rotation of the disc III in counterclock- 60 wise direction the pin I43 contacts tine I42, and continuedrotation in the same direction mov'es switch bar I39 to the position shown by dotted lines in Figure 6, turning the cam I38 therewith. In this position the movable switch member 63 becomes bowed and contacts fixed switch member 64 by reason of the eccentric cam I38 moving it outward; while the other switch member 66 straightens and breaks contact with fixed switch member 18. Thus, wire 12 is removed from the 70 circuit while wire I2 is placed in the circuit. This turn occurs substantially at the point indicated by the dotted arrow 11 on Figure 1b.

In order to return the switch bar I39 to'its original position after this action, the opposite 7 end of the switch bar has tines I4I', I42 thereon,

I40 integral therewith,

and a pin I43 is suitably secured on the disc III near its center. This pin I43 is located so that after the switch bar has moved to the position shown in dotted lines and disc III continues to rotate in the direction of the arrow till the contact I3 passes plate II1 it contacts the tine I42 at about 85% of a revolution and returns the bar to its original full line position. This return action to the full line position takes place near the point designated by dotted arrow I3 with the direction of rotation indicated by the arrow on Figure-1b, and therefore returns wire 12 into the circuit just before contact I3 reaches plate I09. 1

When the direction of rotation of disc III is reversed so that it rotates in a clockwise direction (Figure 1b), the pin I43 will contact with tine I4 I of. bar I'39 to rotate the bar from the full line position to the dotted line position to place wire I2 in the circuit at the position of contact 11 indicated by the dotted arrow 11, and on continued rotation of disc III when contact I3 reaches the position of the dotted arrow I3 (Figure 11)) pin I43 will engage tine I4I to rotate bar 139 again to the full line position thereby returning wire 12 into the circuit just after contact 11 passes plate II1. As hereinbefore explained when the liquid level is such as to cause wires I2 and 12 to oscillate with the contacts I3 and 11 lying between the full line arrow 11 and dotted line arrow 11 in Figure 1b, a play of about ten per cent of a revolution is permitted without operating the automatic switch. As shown in Figure 6, the contact 11 and Wire 12 are in the circuit at about the 115% position and rotation-on the disc causes the switch bar I39 to shift to the dotted line position thus introducing contact I3 and wire I2 into the circuit. Now, should the rotation of the discs be reversed because of a decrease in liquid level the pin I43 is so located that it will not shift switch bar I39 back to the full line position until about the position of dotted arrow I3 at the 5% position is reached. Thus it will be seen there is a play of about in the switch shifting action of pins I43 and I43. When the contacts lie between the dotted arrow position 11 at 75% of a revolution and arrow 11 at 85% of a revolution a similar lag in switch action occurs.

In order to provide a snap action for making and breaking the switch contacts just described, a collar I60 is secured to the opposite end of the shaft I36, and an L-shaped rod or pin I6l is threadedly secured therein and held against turning by a suitable lock nut.

. I63 are in line the switch will be on dead center and in this position the spring I66 will be ineffective, butthe slightest turning movement of the collar I60 will bring the point I63 out of line with the points I36 and-I64 so that the spring will then act with a snap action to turn the shaft I36 inone direction or the other depending. on the direction of rotation until either of the stop The bent end I63 of the pin -I6I and the shaft I36 cooperate pins I69 or I10 abut against stop pin I68 to limit the turning movement. The initial rotation of .the pin I63 to cross the dead center line is accomplished by the pin I43 contacting during the turning of discs H0 and III with one or the otherof the tines I or I42 to swing the bar I39 about the shaft I36 to which it is secured as a pivot and once dead center'has been passed the spring pulling on the pin I6I turns the shaft I36 10 to simultaneously open one set of the switch contacts, as for example, 66, 18,and close the other set 63, 64. Thus, the shaft I36 will always be in position with either stop pin I69 or I10 abutting stop pin I68 except when being moved by either pin I43 or-I48' acting on bar I39.

A third disc I15 similar to discs H0 and III is secured to a sleeve I16 loosely journalled on the central shaft I03 so as to be rotatable independently thereof, and a gear wheel I11 likewise is secured to this sleeve. Longitudinal movement of the sleeve I16 0n the shaft I03 is confined by the collars I18 and I19 suitably secured to the shaft. The sleeve I16 and disc I15 are rotated through gearing consisting of the pinion I80 secured to the end of the shaft I03 which rotates gear wheel I5I secured to a counter shaft I82 which has the pinion I83 thereon which meshes with the gear wheel I11 to rotate the latter, It will be apparent that by reason of the reduction.

0 gearing between discs II 0 and III and disc I15 for each revolution of discs H0 and III, disc I15 makes only a fraction of a revolution, depending on the reduction effected by the gearing. Reduction gearing can be employed to secure any 5 desired ratio of revolutions between the discs I15, and H0, III. 1

The sliding contact wire 22 is wound around the edge 01 the disc I15 and is clamped in place at its ends by a suitable plate I85 of non-conducting material suitably secured to the disc. One end24 of the wire'passes through the disc I 15 and contacts with a collector ring 26 while a suitable auxiliary resistance 16 in the disc is interposed between the other end 25 and a collector ring 21. A spring pressed contact 23 insulated from the frame I00 makes sliding contact with the wire 22 during its travel. An abutment member I95 threadedly secured in the bottom portion of the frame I00 coacts with suitable stops I9C and I91 on the gear wheel I11 to limit rotation thereof and of the disc, I15 in either direction so that the brush 23 will not contact plate I85. Spring brush members 28 and 29 suitably secured to the shelves HI and I12 on the frame I00 and insulated therefrom resiliently bear on the collector rings 26 and 21 respectively, and have lead wires 51 and 53 secured thereto which at their other ends are secured to suitable binding posts. A suitable lead wire 6| connects the sliding contact 23 with a binding po t Referringto Figure '1 the switch member S is located at one corner of the case 85 and is so.- cured to the cover 86 in any suitable manner.

This switch member comprises separate, movable contact members 53 and 50 secured to a shaft 2| I adapted to make contact simultaneously with the fixed contacts 5I and 55 or with 52 and 54. Referring to Figure 1, it will be seen that when switch-members 53 and 50 contact members 5I and. 55 the receiver is connected to show the height of liquid in feet andwhen switch members 53 and 50 contact members 54 and 52 the receiver shows the height in inches; To eliminate the 7 ossibility of error by reading the wrong scale the inch scale is adapted to be covered when contact suitably pivoted at 2I5 to the cover 86. It will be seen that when the switch elements 53 and 50 are moved to contact members 5I and 55 the cam 2I2 is shifted about with the shaft 2I I to the dotted line position, and the weight of the bell crank lever 2H and shutter 2i 3 moves the shutter down to a position to cover scale G leaving scale F visible through the opening or window M in the cover 90. In this position the disc 81 is rotated by the knob 89 until the galvanometer 36 registers zero at which point the reading of the scale is taken at the lowest full foot. The switch is then shifted to contact members 52, 54 whereupon the cam 2I2 rotates the bell crank scale. and the toggle switch breaks contact with 11 and makes contact with I3 thereby completely unbalancing thecircuit. To reestablish the balance the receiver scale must be moved to thecorre sponding point on the black scale G, which will be about 1.8 inches.

nection with Figure 111, this point corresponding to about 10.2 inches on the black scale.

circuits involves no effect on the receiver.

The relationship of transmitter rotation in a reverse direction as the function to be measured decreases in value to the receiver scales, will be readily understood from the foregoing description of the manipulation of the receiver and the description of Figures 1 and 1b.

The toggle switch isso arranged as previously explained that the wires I2 and 12 can be rotated a considerable distance near the change over points without throwing thesswitch, so that after the switch is thrown a slight reverse rotation of the wires I2 and 12 will not immediately return the switch. This feature of operation is of particular value when a recording receiveristobeused.

lnthemodiflcationshowninmuresiiand 9 there is illustrated a suitable support 250 having two partitions or shelves therein 251 and 252 suitably secured in position. A shaft 253 passes through the upper partition 252 and has a pinion 254 on the lower end thereof while the shaft 255 suitably journalled in a lower partition, has the gear 256 on its end. Driving connection between the shafts 253 and 255 is established through the pinion 254, gear 251 mounted on a counter shaft 258 suitably journalled in the partition 252, and through the pinion 259 secured thereto, to the gear 256. In the modification shown a series of contacts 260 having suitable equal resistances 261 secured therebetween is mounted in the top partition 252 and corresponds in function with the slide wire 12 in the modification just described. A rotary contact member 262 suitably secured to the shaft 253 to rotate therewith, but insulated therefrom by a collar 263, is adapted to make sliding contact with the contacts 260, and a brush member 264, making sliding contact with a metal collar 265 in contact'with the arm 262, is secured to the frame 250. On the bottom partition are mounted similar contacts 210 having resistances in: terconnecting the same, and a contact arm 212 l is mounted on the shaft 255 and insulated therefrom. The contact 212 is electrically connected to a metal contact ring 213 mounted on the shaft 255 and a brush member 214 suitably secured in the frame 250 makes sliding contact therewith.

The operation of this modification will be apparent by consideration of Figure 10. The 'ends 215 and 216 of resistance 260 form part of an electrical circuit including'a battery, and the sliding contact arm 262 makes sliding contact with the resistance 260 which conducts current through the brush 264 and galvanometer 211 to a resistance 218 equal to resistance 260. The resistance 210 likewise forms a part of an electrical circuit including a battery, the ends 219 and 280 of the resistance being connected in the circuit, and the contact member 212 making sliding contact with the resistance 210 being connected through the brush member 214 and galvanometer 281 with an equal resistance 282. The resistance 218 will be graduated in large units, and the resistance 282 will be graduated in fractional units. If it is desired to obtain the reading in the tank, the contact 283 is moved along the resistance 218 until the galvanometer shows zero deflection, and the graduations on the resistance are read to obtain the reading of the apparatus in feet. To obtain accurately the reading of the last fractional foot the contact 284 is moved along the resistance 282 until the galvanometer shows zero deflection and the reading of resistance 282 then is taken. The sum of the readings at 282 and 218 accurately give the reading of the level of liquid in a tank. If desired, the

apparatus shown in Figures 8 and 9 can be used with the receiver shown in Figure 1. Figure 11 shows a modification involving a different electrical circuit. In this modification the galvanometer 211 is shunted across the battery circuit and the sliding contacts 262 and '283 are connected in series in the battery circuit, that is the battery and galvanometer-are interchanged from the modification shown in Figure 10. In this modification the reading is taken the same as in Figure 10, that is the sliding contact 283 is moved along the resistance 218 until the galvanometer shows zero deflection, and the reading 75 then is taken. A similar modification would be employed for obtaining the reading in small units for the resistance 210.

In the modification shown in Figure 12 the resistance 263 is balanced across a pair of variable capacitors 285, 286 which are manually varied until position of zero deflection in the galvanometer 211 is obtained. The reading of these capacitors then gives the liquid level in the tank.

Figure 13 shows a modification employing alternating current. In this modification the resistance. 263 is balanced across two variable in-' ductances 281, 288 with an earphone 289 interposed in between, and the inductances 281, 288 are manually adjusted until humming in the earphone is eliminated whereupon they are read to show the level of liquid in the tank.

In Figure 14 is shown a schematic diagram of a modification in which two variable inductances 290 and 291 are balanced against two variable inductances 281, 288, with the earphone 289 in between, this system also employing alternating current. In this modification the inductances 290 and 291 are varied by the operation of the float in the tank and the inductances 281, 288

are manually adjusted until there is no hum-- ming in the earphone 289 whereupon the reading is taken. In all the modifications above described a similar circuit is employed for obtaining the reading in the small unit system.

In Figure 15 is diagrammatically shown a modification suitable for long distance transmission over telephone lines. In this modification the unit resistance wire 301 forms part of a potentiometer circuit having the battery 302 therein and connected thereto at its ends by lead wires 303 and 304. The wire 301 has a sliding contact 305 thereon adapted to be moved therealong by a float or similar actuating device and the sliding contact 305 is connected by a lead wire 306 to one terminal 301 of a relay 308. The purpose of this relay will be described hereinafter. The contact arm 311 of the relay is constructed to remain in a given position until actuated and as shown, the arm 311 closes contact with a lead wire 312- connected to a resistance 313 which in turn is connected to a lead wire 314 connected to contact 315 of a second similar relay 316. As shown the arm 311 of this relay connects to the lead wire 318 joined to a telephone wire 319. One end of resistance 301 is likewise connected by a lead wire 321 to a contact 322 of a similar relay 323 in which the arm 324 connects with the wire 325 connected to a telephone wire 326.

The receiver comprises a resistance 331 similar to resistance 301 and connected to the battery '332 through a variable resistance 333 and sliding contact 334 whereby the potential drop across wire 331 can be changed so as to equal the potential drop across wire 301. A sliding contact 335 is manually movable along wire 331 and is connected by the lead wire 336 to a single pole switch 331 which in turn is connected to a galvanometer 338 and by a lead wire 339 to telephone wire 319. The one end of wire 331 is connected by a lead wire 341 to telephone wire326.

From the description so farpursued, it will be seen that the battery 302, resistance 301, connecting leads 303 and 304 and sliding contact 305 constitute a potentiometer circuit and that as the contact 305 is moved along wire 301 in response a to changes in the level of liquid to be measured the potential between the ends of wire 301 'and contact 305 is changed. The potential difference is conducted through wire 306, relay 308, wire 312 to relay 316, and through wire 318 to the tele-' phone wire 319. From there it goes through wire 333 through galvanometer 3311, switch 331 and lead wire 336 to contact 335 slidably engaging wire 331. The one end of wire 301,.conducts the potential difference through wire 321, relay 323 and wire 325 to the other telephone wire 326, and from there through wire 341 to the corresponding end of wire 331. Initially the sliding contact 334 is set so that the "potential drop across wire 331 is equal to the potential drop across wire 3111 in a manner to be described. The galvanorneter 338 will show zero deflection when sliding contact 335 is set at a position on wire 331 corresponding to the position of sliding contact 335 on wire 3111.

By means of a scale on wire 331 the height of liquid in the tank can be read in feet by the position of contact 335. A switch 342 can be employed for shunting the galvanometer to prevent injury thereto when closing relay switches 311 or 381 for throwing the relays as will be described hereinafter.

The fractional unit measuring device comprises a potentiometer circuit exactly like the unit device, and consists of a similar slide wire 351, battery 352, lead wires 353 and 354, and a sliding contact member 355. The sliding contact 355 is connected by a lead wire 356 to a contact 351 of the relay 358,. and the arm 361 thereof is connected to a wire 362, resistance 363 and wire 364 to the other contact member 365 of relay 316. I

One end of wire 3-51 is connected by wire 366 to the contact 361 of relay 323.

In order to permit the use, of a single receiving unit for both the unit and fractional unit device a system of relays is employed for cutting one of the units out of the circuit while a measurement is being made with the other unit. The

relay system is also used in checking the transmitting potentiometer circuits against the -receiving potentiometer circuit. As shown, the arms of relays 303, 316, 323 and 358 are in position for measurement of the liquid level in large units on wire 301. For shifting the relays to cut out wire 301 and introduce wire 351 into the transmitting circuit a relay shifting circuit is provided comprising a battery 3111 connected to a double pole switch 311, one terminal of which is grounded. The one terminal of both relays 316 and 323 likewise is grounded. In one position of switch 311 the relay arms 311 and 324 will take the position shown closing contact between contact 315 and wire 313 of relay 316, and between contact 322 and wire 325 of relay 323. Then upon opening switch 311 the relay arms will remain in this position, and the unit transmitter will now be in the circuit. To cut out the unit transmitter and insert the fractional unit transmitter the double pole switch 311 is shifted to its other position thereby sending an actuating current through the system which throws the relay arms 311 and 324 to the dotted line position. In this position the potential difference in wire 351 is transmitted through relay 316 by arm 311 which closes contact between contact 365 and wire 313 to the telephone wire 319, and through relay 323 by arm 324 which closes contact between contact 361 and wire 325 to the telephone wire 326. At the same time by the relay arms 311 and 324 breaking contact with contacts 315 and 322 theunit transmitter is cut out of the circuit. By shifting the sliding contact 335 along wire 331 as hereinbefore, described and by the use of a suitable fractional unit scale the reading of the fractional unit transmitter can be taken.

The following arrangement is employed for checking the transmitting and receiving circuits. The unit transmitter wire 301 makes a fixed connection with wire 315 which is connected to contact 316 of relay 308, and the receiver wire 331 likewise makes a fixed connection with wire 311 at a corresponding point thereon. Therefore the connections at 315 and 311 divide the respective slide wires 3111 and 331 proportionally. In the position of the relays 316 and 323 shown it is necessary to employ a. circuit for throwing the position to return the relay arm 311 to the full line position shown.

The fractional unit transmitter has a wire 335 similarly connected to the fractional unit resistance wire 351, and is connected to the contact 386 of the relay 358. To check the fraction-- al unit transmitter the switch 311 is first thrown to actuate relays 316 and 323 and thereby cut out the unit transmitter from the circuit and cut in the fractional unit transmitter.

by shift the arm 361 to make contact between wire 362 and contact 386 whereupon the circuit can be checked as heretofore described. The resistances 313 and 363 are inserted to prevent the relay actuating current from being dissipated through the measuring circuit.

The invention may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. The present embodiment is therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein.

What is claimed and desired to be secured by United States Letters Patent is:-

1. In a tank gauge, a rotatable member having a circular resistance thereon, means operated by a motion to be measured for rotating said member, a stationary contact for contacting said resistance intermediate its ends, a guard for raising said contact to prevent contact at the ends of said resistance, a second member having a second circular resistance thereon and rotatable with said first member, the ends of said second resistance being disposed in angular relation to the ends of said first resistance, a second stationary contact for contacting said second re-- sistance intermediate its ends, and a second guard for raising the second contact to prevent contact at the ends of the resistance, a switch, operating means for said switch to shift connection from one contact to the other when the respective guards break contact between the contacts and resistance, an electrical indicating circuit, and switch means for connecting said reslstances into said indicating circuit.

2. In an apparatus of the character described, a rotatable disc, a ring conductor on said disc, a slide wire resistance secured about the periphery of said disc'and having one end contacting with said ring conductor, a brush member making sliding contact with the exposed part of said The switch 381 is then thrown to actuate relay 358 and there-' resistance, a second disc movable in unison with the first disc, a second ring conductor thereon, an auxiliary resistance secured between the other end of the slide wire and the second ring conductor, a second slide wire secured about the periphery of the second disc and having one end contacting with the second ring conductor, a second auxiliary resistance equal to thefirst auxiliary resistance secured between the other end of the second slide wire and the first ring conductor, a second brush member making sliding contact with the exposed part of the second resistance, a. balancing circuit including the ring conductor and means for disconnecting one or the other of said brush members from the respective slide wire resistances through a portion of the movement of said discs, and means operable while both brushes are engaging their respective slide wires to place one or the other of said brushes in the balancing circuit.

3. In a tank gauge, a rotatable member having a circular resistance thereon, means operated by a motion to be measured for rotating said memher, a stationary contact for contacting said resistance intermediate its ends, a guard for raising said contact to prevent contact at the ends of said resistance, a second member having a second circular resistance thereon and rotatable with said first member, a second stationary contact for contacting said second resistance intermediate its ends, and a second guard for raising the second contact to prevent contact at the ends of the resistance, a switch, operating'means for said switch to shift connection from one contact to the other when the respective guards break contact between the contacts and resistance, a third resistance element and a third contact adapted to contact said third resistance element, the third resistance element and the third contact being relatively movable and in synchronism at a predetermined different rate with the first and second named resistance elements and contacts, an electrical indicating circuit, and switch means for selectively connecting said resistance elements into said indicating circuit.

GARRE'IT B. LINDERMAN, JR. 

